critical materials and their impact on...
TRANSCRIPT
Critical Materials and
Their Impact on Technology
Alex King
2
What is a “Critical Material?”
• Any substance used in technology that is
subject to supply risks, and for which there
are no easy substitutes.
• Or, in plain English – stuff you really need
but can’t always get.
• The list of materials that are considered
critical depends on who, where and when
you ask.
• CMI focuses on clean energy technologies,
in the US, over the next 10 to 15 years.
3
Materials criticality is affecting us today
• Jet engine manufacturers,
including CMI partner GE, have
had to deal with shortages of
rhenium. – http://www.gereports.com/engineering-ways-to-
reduce-the-rare-metal-rhenium-in-jets/
• A major disk-drive manufacturer
came within one week of shutting
down production for lack of Nd-
Fe-B magnets.
4
Materials criticality is affecting us today
• Loudspeaker manufacturers
have been severely impacted
by magnet price increases.
• Tesla Motors feared being
forced to reduce production
because of short supplies of
Li-ion batteries.– http://wheels.blogs.nytimes.com/2013/09/
06/as-it-increases-production-tesla-worries-about-battery-supply/?_r=0
5
Materials criticality is affecting us today
• Even military hardware is
occasionally being sourced
from China, because of the
lack of a domestic supply-
chain for certain key
materials.
http://www.reuters.com/article/2014/01/03/us-lockheed-f-idUSBREA020VA20140103
6
Materials criticality is affecting us today
• The target date for transition to high-output T5 fluorescent lamps has been delayed by two years because manufacturers claim that there is a shortage of Eu and Tb for the phosphors.
• Utility-scale wind turbine installations are overwhelmingly gearbox-driven units, despite the high failure-rate of the gearboxes, because of the cost and unavailability of Nd and Dy required for direct-drive units.
7
Wind turbine failures
WMEP: the Wissenschaftliches Mess- und Evaluierungsprogramm (WMEP) database was accomplished from 1989 to 2006 and
contains failure statistics from 1,500 wind turbines.
LWK: failure statistics published by Landwirtschaftskammer Schleswig-Holstein (LWK) from 1993 to 2006. It contains failure data
from more than 650 wind turbines.
8
Wind turbine evolution
Source: NREL Technical Report, NREL/TP-5000-61063, January 2014
5
This report is available at no cost from the National Renewable Energy Laboratory (NREL) at www.nrel.gov/publications.
Project Motivation and Objectives
The average size and height of land-based wind turbines installed in the United States has
increased over time as indicated in Figure 1. At the same time, the levelized cost of energy
(LCOE) from wind turbines has, for the most part,1 declined in part as a result of the increased
economies of scale associated with larger turbines [1]. Technologies that enable larger wind
turbines on taller towers create opportunities for further LCOE reductions. However,
transportation and logistics challenges limit the size and tower height of land-based turbines that
can be deployed in the United States. Addressing these transportation and logistics challenges
will allow for deployment of larger state-of-the-art turbines, which may accelerate the
development of new markets in low- and moderate-wind-speed regions in the United States and
enable LCOE reduction pathways for all land-based wind turbines.
In addition, although U.S. manufacturing opportunities are not clear cut, the components
required for larger wind turbines, such as the blades, can be manufactured more cost-
competitively in the United States as opposed to being imported [2]. As a result, domestic
content and U.S. manufacturing competitiveness may be increased by addressing challenges that
limit the deployment of larger turbines.
Figure 1. Average land-based wind turbine size and levelized cost of energy through 2012, and range of state-of-the-art turbines that could be deployed by addressing barriers
1 An array of factors contributed to the temporary increase in turbine prices in the mid-2000s, including increases in
raw material prices and energy prices, supply constraints, increasing OEM profitability and labor costs, and
manufacturer warranty provisions.
9
Magnet Requirements
• For permanent-magnet direct-drive wind turbines, an Nd-Fe-B generator magnet weighs about 0.5 tonnes of magnet per megawatt of peak rated power.
• This translates to about 0.13 tonnes of rare earth per megawattof peak rated power.
• European offshore wind capacity is growing at nearly 5,000MW per year, creating a demand for ~650 tonnes of rare earths.
• Annual world production of Nd metal is ~16,500 tonnes.
10
Critical materials are not new
• “The stone age did not end for lack of stone” –Sheik Ahmed Zaki Yamani.
• The copper age replaced the stone age because copper was better for some things.
• The bronze age replaced the copper age because bronze was better than copper.
• But the bronze age was not replaced by the iron age. It ended because copper became unavailable.
11
Iron vs. Bronze, 1200 BC
• Processing
– Bronze is manufactured at lower temperatures
• Hardness
– Bronze is better, because no effective hardening mechanisms are yet available for iron.
• Corrosion
– Bronze is better
• Cost
– Iron is nine times more expensive than gold
12
Bronze age trade and industry
Wikipedia (After M. Otte (2007) Vers la Préhistoire, de Boeck, Bruxelles)
13
The Bronze Age Collapse ~1200 BC
• “Global” events
– Natural disasters: earthquakes, climate change, famine
– Wars, revolts, invasions
– Collapse of trade; collapse of civilization
• Bronze becomes unavailable
– Possibly because Cyprus is overtaken by war, making copper inaccessible.
• Responses include
– Recycling
– Source diversification
– Materials substitution: eventual emergence of the iron age
14
How is criticality assessed?
DOE Medium Term Outlooks: 2015 – 2025
• Identifies the propensity for
supply-chain problems to occur.
It does not predict that they will.
• Identifies the need for
appropriate attention, not panic.
• Depends on location, industry-
sector, and time.
15
Critical materials for the European Union
European Commission, May 2014
16
EU critical materialsfor decarbonization
17
Why should we worry? Long-term price trends are quite reassuring
18
OECD expects the world’s middle class to grow -
from1.8 billion people, in 2012,
to 4.9 billion in 2030.
http://www.reuters.com/middle-class-infographic
But… there are more consumers coming
19
Ore grades are declining
20
Co-production helps to provide supplies of many minor metals, but it also causes inelasticity of supply.
Cu
Ni
AlZn
Sn
PGM
P
b
Mo Re
As
Bi
AgAu
Co
Se
T
e
In
Ge
Ta
Nb
Ga
Ti
Z
r
H
f
Co-production is becoming dominant
21
Technology is growing more complex
~30 elements ~75 elements
H He
Li Be B C N O F Ne
Na Mg Al Si P S Cl Ar
K Ca Sc Ti V Cr Mn Fe Co Ni Cu Zn Ga Ge As Se Br Kr
Rb Sr Y Zr Nb Mo Tc Ru Rh Pd Ag Cd In Sn Sb Te I Xe
Cs Ba La Hf Ta W Re Os Ir Pt Au Hg Tl Pb Bi Po At Rn
Fr Ra Ac Rf Db Sg Bh Hs Mt Ds Rg Cp Fl Lv
Ce Pr Nd Pm Sm Eu Gd Tb Dy Ho Er Tm Yb Lu
Th Pa U Np Pu Am Cm Bk Cf Es Fm Md No Lr
H He
Li Be B C N O F Ne
Na Mg Al Si P S Cl Ar
K Ca Sc Ti V Cr Mn Fe Co Ni Cu Zn Ga Ge As Se Br Kr
Rb Sr Y Zr Nb Mo Tc Ru Rh Pd Ag Cd In Sn Sb Te I Xe
Cs Ba La Hf Ta W Re Os Ir Pt Au Hg Tl Pb Bi Po At Rn
Fr Ra Ac Rf Db Sg Bh Hs Mt Ds Rg Cp Fl Lv
Ce Pr Nd Pm Sm Eu Gd Tb Dy Ho Er Tm Yb Lu
Th Pa U Np Pu Am Cm Bk Cf Es Fm Md No Lr
22
Technology emergenceCase study: electric vehicles
Assumption: The market penetration of EVs will rise when a battery
technology emerges that provides all-electric range close to that of a single
tank of gasoline, if the price premium is similar to that of a hybrid.
• ~15,000,000 new cars are sold in the US every year.
• ~7% of new car sales in California are hybrids.
• Guess that the market for an all-electric vehicle could rise to 1,000,000 per year.
• If the battery requires 20kg of “unobtainium” the demand is around 20,000
tonnes, for US consumption alone. This is a small percentage of current world
production for some elements, but a very large percentage for others.
23
Source: US Dept. of Energy – Energy Savings Forecast of Solid-State
Lighting in General Illumination Applications (August 2014)Source: US Dept. of Energy – Energy Savings Potential of Solid-State
Lighting in General Illumination Applications (January 2012)
Technology shifts: lighting
• Why did the forecast change so much in 2 years?
• What is the impact on materials demand
24
White LED materials
Lumileds® Luxeon® emitter (via LEDs Magazine)
• InGaN LED chip produces
blue light
• Ceria-doped YAG particles
embedded in the silicone
encapsulent absorb some of
the blue and emit a broad
spectrum of visible light,
producing the desired white
light.
25
A three-pillared research strategy
Find ways to:
• diversify our sources;
• provide alternatives to the existing materials;
• make better use of the existing supplies through recycling and re-use.
Some of these approaches work better than others for specific materials.
26
Unfortunately, these approaches are slow to have impact
• Mine development, where there is a known resource, takes about 15 years, and has costs in the billions of dollars.
• Development and deployment of new materials takes an average of 18 years.
• There are no empirical data to suggest how long it takes for recycling programs to have an impact.
27
Two grand challenges
• Starting sooner– We need to anticipate criticality, not just respond to it.
• Working faster, faster– 200 years at ~1000 BC
– 20 years at ~ 2000 AD
– 2 years by ~ 5000 AD?
28
The opposite of a critical material
• Stuff you really need to get rid of, if only you could
– Lead; Mercury; Beryllium; Thorium; Cerium; Lanthanum; Cobalt…
• Drivers
– Economics
– Regulations: Reach, RoHS, Dodd-Frank…
• We call these ANACRITICAL materials
– As with critical materials, the list might vary depending on who, when or where you ask.
– Technical solutions often mirror those for critical materials.
29
Thank You!
Questions?
30
Separation and beneficiation are difficult
• Hard disk drives contain two types of Nd2Fe14B magnet– Voice coil magnet(s)
– Spindle magnet
• This is the biggest single use of these magnets, consuming
almost 20% of the worldwide production
• There is currently no cost-effective
strategy for recycling them.– Shred the drive and separate?
– Extract the magnets first?
– Demagnetize before or after?
– Data security issues?
31
Pure metalCrude metalPregnant liquor
PowderRock
Metal production stages (schematically)
Mining Crushing
Ore mineralLeachate BeneficiationDigestionSeparation
Reduction Refining
32
Pure metalCrude metalPregnant liquor
ShardsDevices
Recycling stages (schematically)
Collection Crushing
Separated flakesLeachate BeneficiationDigestionSeparation
Reduction Refining
33
A popular alternative approach: espionage!